Solid-State Electronics, Vol.53, No.8, 816-823, 2009
Molecular approaches to p- and n-nanoscale doping of Ge1-ySny semiconductors: Structural, electrical and transport properties
We report the development of practical doping protocols via designer molecular sources to create n- and p-type doped Ge1-ySny layers grown directly upon Si(100). These materials will have applications in the fabrication of advanced PIN devices that are intended to extend the infrared optical response beyond that of Ge by utilizing the Sri composition as an additional design parameter. Highly controlled and efficient n-doping of single-layer structures is achieved using custom built P(GeH3)(3) and As(GeH3)(3), precursors containing preformed Ge-As and Ge-P near-tetrahedral bonding arrangements compatible with the structure of the host Ge-Sn lattice. Facile substitution and complete activation of the P and As atoms at levels similar to 10(17)-10(19) cm(-3) is obtained via in situ depositions at low temperatures (350 degrees C). Acceptor doping is readily achieved using conventional diborane yielding carrier concentrations between 10(17)-10(19) cm(-3) under similar growth conditions. Full activation of the as-grown dopant concentrations is demonstrated by combined SIMS and Hall experiments, and corroborated using a contactless spectroscopic ellipsometry approach. RTA processing of the samples leads to a significant increase in carrier mobility comparable to that of bulk Ge containing similar doping levels. The alloy scattering contribution appears to be negligible for electron carrier concentrations beyond 10(19) cm(-3) in n-type samples and hole concentrations beyond 10(18) cm(-3) in p-type samples. A comparative study using the classical lower-order hydrides PH3 and AsH3 produced n-doped films with carrier densities (up to 9 x 10(19) cm(-3)) similar to those afforded by P(GeH3)(3) and As(GeH3)(3). However, early results indicate that the simpler PH3 and AsH3 sources yield materials with inferior morphology and microstructure. Calculations of surface energetics using bond enthalpies suggest that the latter massive compounds bind to the surface via strong Ge-Ge bonds and likely act as "retardants" that moderate surface diffusion of the reactions species, thereby promoting layer-by-layer growth leading to thick, atomically smooth films, particularly in the case of P(GeH3)(3). Furthermore, the intact incorporation of the Ge3P and Ge3As molecular cores results in highly uniform compositional, strain and doping profiles at the atomic level. (C) 2009 Elsevier Ltd. All rights reserved.